Tensor-induced CMB temperature-polarization correlation in reionized universes

We demonstrate that the cosmic microwave background (CMB) temperature-polarization cross-correlation provides accurate and robust constraints on cosmological parameters. We compare them with the results from temperature or polarization and investigate the impact of foregrounds, cosmic variance, and instrumental noise. This analysis makes use of the Planck high-ℓ HiLLiPOP likelihood based on angular power spectra, which takes into account systematics from the instrument and foreground residuals directly modelled using Planck measurements. The temperature-polarization correlation (TE) spectrum is less contaminated by astrophysical emissions than the temperature power spectrum (TT), allowing constraints that are less sensitive to foreground uncertainties to be derived. For ΛCDM parameters, TE gives very competitive results compared to TT. For basic ΛCDM model extensions (such as AL, ∑mν, or Neff), it is still limited by the instrumental noise level in the polarization maps.

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CMB Temperature Polarization Correlation and Primordial Gravitational Waves: WMAP5

Advances in Astronomy ◽

10.1155/2009/309024 ◽

2009 ◽

Vol 2009 ◽

pp. 1-5

Author(s):

N. J. Miller ◽

B. G. Keating ◽

A. G. Polnarev

Keyword(s):

Power Spectrum ◽

Gravitational Waves ◽

Cross Correlation ◽

Statistical Tests ◽

Density Perturbation ◽

Wiener Filters ◽

Primordial Gravitational Waves ◽

Temperature Polarization ◽

Source Of Information ◽

Cmb Temperature

we continue our study of the CMB temperature polarization (TE) cross-correlation as a source of information about primordial gravitational waves (PGWs). In a previous paper, we considered two methods for detecting PGWs using the TE cross-correlation. The first method is the zero multipole method, where we find the multipole,ℓ0, where the TE cross-correlation power spectrum,CℓTE, first changes sign. The second method Wiener filters the CMB TE data to remove the density perturbation contribution to the TE power spectrum. We then use statistical tests to determine if there is a detection of negative residual TE correlation and hence a detection of primordial gravitational waves, the only source of negative TE correlation at these superhorizon scales. In this paper, we will apply these tests to the WMAP 5-year data. We find that the TE power spectrum consistent withr< 2.0 at 95% confidence with no additional assumptions about the PGWs. If we assume that the PGWs are generated by inflation, then we getr< 1.0 at 95% confidence.

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First‐Year Wilkinson Microwave Anisotropy Probe ( WMAP ) Observations: Temperature‐Polarization Correlation

The Astrophysical Journal Supplement Series ◽

10.1086/377219 ◽

2003 ◽

Vol 148 (1) ◽

pp. 161-173 ◽

Cited By ~ 742

Author(s):

A. Kogut ◽

D. N. Spergel ◽

C. Barnes ◽

C. L. Bennett ◽

M. Halpern ◽

...

Keyword(s):

Wilkinson Microwave Anisotropy Probe ◽

First Year ◽

Temperature Polarization ◽

Polarization Correlation

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COSMIC COVARIANCE AND THE LOW QUADRUPOLE ANISOTROPY IN THE WMAP DATA

Modern Physics Letters A ◽

10.1142/s0217732308027874 ◽

2008 ◽

Vol 23 (17n20) ◽

pp. 1489-1497 ◽

Cited By ~ 7

Author(s):

LUNG-YIH CHIANG ◽

PAVEL D. NASELSKY ◽

PETER COLES

Keyword(s):

Monte Carlo ◽

Monte Carlo Simulations ◽

A Priori ◽

Gaussian Random Field ◽

Minimum Variance ◽

Microwave Background ◽

Data Release ◽

Intrinsic Correlation ◽

Wmap Data ◽

Cmb Temperature

Low quadrupole power in the cosmic microwave background (CMB) temperature anisotropies has been a puzzle since WMAP data release. In this talk I will demonstrate that the minimum variance optimization (MVO), a methodology used by many authors including the WMAP science team to separate the CMB from foreground contamination, serves not only to extract the CMB, but to subtract the “cosmic covariance”, an intrinsic correlation between the CMB and the foregrounds. Such subtraction induces low variance in the signal via MVO, which in turn propagates into the multipoles, causing a quadrupole deficit with more than 90% CL. As we do not know the CMB and the foregrounds a priori, and their correlation is subtracted by the MVO in any case, there is therefore an unknown error in the quadrupole power even before the cosmic variance interpretation. We combine the MVO and Monte Carlo simulations, assuming CMB is a Gaussian random field, and the estimated quadrupole power falls in [308.13, 401.97] μ K 2 (at 1 − σ level).

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